Method and apparatus for state/mode transitioning

ABSTRACT

A method and apparatus for transitioning states or modes on a user equipment, the method having the steps of receiving, at a network element, a transition indication; checking a radio resource profile for the user equipment; and making a transitioning decision at the network element based on the received transition indication and the radio resource profile.

RELATED APPLICATIONS

This application is a continuation of application Ser. No. 12/107,514, filed Apr. 22, 2008 now U.S. Pat. No. 8,208,950, which claims priority from U.S. application No. 60/987,672, filed Nov. 13, 2007, entitled “Method and Apparatus for State/Mode Transitioning Based on a Radio Resource Profile”, the contents of which are incorporated herein by reference.

FIELD OF THE DISCLOSURE

The present disclosure relates to radio resource control between User Equipment (UE) or other wireless or mobile device and a wireless network, and in particular to transitioning between states and modes of operation in a wireless network such as for example, a Universal Mobile Telecommunication System (UMTS) network.

BACKGROUND

A Universal Mobile Telecommunication System (UMTS) is a broadband, packet-based system for the transmission of text, digitized voice, video and multi-media. It is a highly subscribed to standard for third generation and is generally based on Wideband Coded Division Multiple Access (W-CDMA).

In a UMTS network, a Radio Resource Control (RRC) part of the protocol stack is responsible for the assignment, configuration and release of radio resources between the UE and the UTRAN. This RRC protocol is described in detail in the 3GPP TS 25.331 specifications. Two basic modes that the UE can be in are defined as “idle mode” and “UTRA RRC connected mode” (or simply “connected mode”, as used herein). UTRA stands for UMTS Terrestrial Radio Access. In idle mode, the UE or other mobile device is required to request an RRC connection whenever it wants to send any user data or in response to a page whenever the UTRAN or the Serving General Packet Radio Service (GPRS) Support Node (SGSN) pages it to receive data from an external data network such as a push server. Idle and connected mode behaviors are described in the Third Generation Partnership Project (3GPP) specifications TS 25.304 and TS 25.331.

When in a UTRA RRC connected mode, the device can be in one of four states. These are:

CELL_DCH: A dedicated channel is allocated to the UE in uplink and downlink in this state to exchange data. The UE must perform actions as outlined in 3GPP 25.331.

CELL_FACH: no dedicated channel is allocated to the user equipment in this state. Instead, common channels are used to exchange a small amount of bursty data. The UE must perform actions as outlined in 3GPP 25.331 which includes the cell selection process as defined in 3GPP TS 25.304. CELL_PCH: the UE uses Discontinuous Reception (DRX) to monitor broadcast messages and pages via a Paging Indicator Channel (PICH). No uplink activity is possible. The UE must perform actions as outlined in 3GPP 25.331 which includes the cell selection process as defined in 3GPP TS 25.304. The UE must perform the CELL UPDATE procedure after cell reselection. URA_PCH: the UE uses Discontinuous Reception (DRX) to monitor broadcast messages and pages via a Paging Indicator Channel (PICH). No uplink activity is possible. The UE must perform actions as outlined in 3GPP 25.331 including the cell selection process as defined in 3GPP TS 25.304. This state is similar to CELL_PCH, except that the URA UPDATE procedure is only triggered via UTRAN Registration Area (URA) reselection.

The transition from an idle to the connected mode and vice-versa is controlled by the UTRAN. When an idle mode UE requests an RRC connection, the network decides whether to move the UE to the CELL_DCH or CELL_FACH state. When the UE is in an RRC connected mode, again it is the network that decides when to release the RRC connection. The network may also move the UE from one RRC state to another prior to releasing the connection or in some cases instead of releasing the connection. The state transitions are typically triggered by data activity or inactivity between the UE and the network. Since the network may not know when the UE has completed data exchange for a given application, it typically keeps the RRC connection for some time in anticipation of more data to/from the UE. This is typically done to reduce the latency of call setup and subsequent radio resource setup. The RRC connection release message can only be sent by the UTRAN. This message releases the signal link connection and all radio resources between the UE and the UTRAN. Generally, the term “radio bearer” refers to radio resources assigned between the UE and the UTRAN. And, the term “radio access bearer” generally refers to radio resources assigned between the UE and, e.g., an SGSN (Serving GPRS Service Node). The present disclosure shall, at times, refer to the term radio resource, and such term shall refer, as appropriate, to either or both the radio bearer and/or the radio access bearer.

The problem with the above is that even if an application on the UE has completed its data transaction and is not expecting any further data exchange, it still waits for the network to move it to the correct state. The network may not be even aware of the fact that the application on the UE has completed its data exchange. For example, an application on the UE may use its own acknowledgement-based protocol to exchange data with its application server, which is accessed through the UMTS core network. Examples are applications that run over User Datagram Protocol/Internet Protocol (UDP/IP) implementing their own guaranteed delivery. In such a case, the UE knows whether the application server has sent or received all the data packets or not and is in a better position to determine if any further data exchange is to take place and hence decide when to terminate the RRC connection associated with Packet Service (PS) domain. Since the UTRAN controls when the RRC connected state is changed to a different state or into an idle mode, and the fact that UTRAN is not aware of the status of data delivery between the UE and external server, the UE is forced to stay in a higher data rate and intensive battery state than the required state or mode, thereby draining battery life. This also results in wasting network resources due to the fact that the radio resources are unnecessarily kept occupied.

One solution to the above is to have the UE send a signaling release indication to the UTRAN when the UE realizes that it is finished with data transaction. Pursuant to section 8.1.14.3 of the 3GPP TS 25.331 specification, the UTRAN may release the signaling connection upon receipt of the signaling release indication from the UE, causing the UE to transition to an idle mode. A problem with the above is that the signaling release indication may be considered an alarm. A network typically only expects the signaling release indication when a GPRS Mobility Management (GMM) service request failure, a Routing Area Update (RAU) failure, or an attach failure occurs. The raising of an alarm when the USE request signaling release results in the raising of an alarm at the network, and the raising of the alarm is erroneous behavior when no abnormal condition has otherwise arisen.

A UE operable in a UMTS, as well as other mobile nodes operable in radio communication systems constructed pursuant to other communication standards, is sometimes capable of providing multiple, concurrent packet data services each pursuant to a packet data communication session. While use of a signaling release indication by a UE sent to a UTRAN would provide a manner by which to request release of a signaling connection provided for all of the packet data services with the UE, there is a need to provide more refined control over the resources. That is to say, there might well be a need, to provide continued radio resources for one of the packet data services which is currently active while releasing the radio resources provided for another of the concurrent packet data services which no longer requires radio resource. This results in efficient usage of network resource as well as optimal utilization of the processor on the UE, as the processor power will not be wasted in processing resources that are not required. A network element may alternatively make a decision concerning the release of resources or the transition between states/modes.

BRIEF DESCRIPTION OF THE DRAWINGS

The present disclosure will be better understood with reference to the drawings in which:

FIG. 1 is a block diagram showing RRC states and transitions;

FIG. 2 is a schematic of a UMTS network showing various UMTS cells and a URA;

FIG. 3 is a block diagram showing the various stages in an RRC connection setup;

FIG. 4A is a block diagram of an exemplary transition between a CELL_DCH connected mode state and an idle mode initiated by the UTRAN according to the current method;

FIG. 4B is a block diagram showing an exemplary transition between a CELL_DCH state connected mode transition to an idle mode utilizing signaling release indications;

FIG. 5A is a block diagram of an exemplary transition between a CELL_DCH inactivity to a CELL_FACH inactivity to an idle mode initiated by the UTRAN;

FIG. 5B is a block diagram of an exemplary transition between CELL_DCH inactivity and an idle mode utilizing signaling release indications;

FIG. 6 is a block diagram of a UMTS protocol stack;

FIG. 7 is an exemplary UE that can be used in association with the present method;

FIG. 8 is an exemplary network for use in association with the present method and system;

FIG. 9 is a flow diagram showing the steps of adding a cause for a signaling connection release indication at the UE;

FIG. 10 is a flow diagram showing the steps taken by a UE upon receipt of a signaling connection release indication having a cause;

FIG. 11 illustrates a graphical representation of exemplary logical and physical channel allocation during exemplary operation of the network shown in FIG. 8 in which multiple, concurrent packet data communication service sessions are provided with the UE;

FIG. 12 illustrates a functional block diagram of UE and network elements that provide for radio resource release function to release radio resources of individual packet data services pursuant to an embodiment of the present disclosure;

FIG. 13 illustrates a message sequence diagram representative of signaling generated pursuant to operation of an embodiment of the present disclosure by which to release radio resource allocation to a PDP context;

FIG. 14 illustrates a message sequence diagram, similar to that shown in FIG. 13, also representative of signaling generated pursuant to operation of an embodiment of the present disclosure by which to release radio resource allocation;

FIG. 15 illustrates a process diagram representative of the process of an embodiment of the present disclosure;

FIG. 16 illustrates a method flow diagram illustrating the method of operation of an embodiment of the present disclosure;

FIG. 17 illustrates a method flow diagram, also illustrating the method of operation of an embodiment of the present disclosure;

FIG. 18 illustrates a method flow diagram of an embodiment in which transitioning decisions are made based on a Radio Resource Profile at a network element;

FIG. 19 illustrates a simplified block diagram of a network element apt to be used with the method of FIG. 18; and

FIG. 20 illustrates a data flow diagram for the sending of a dedicated preferred state request.

DETAILED DESCRIPTION

The examples and embodiments provided below describe various methods and systems for transitioning a User Equipment (UE) or other mobile devices between various states/modes of operation in a wireless network such as, for example, a UMTS network. It is to be understood that other implementations in other types of networks are also possible. For example, the same teachings could also be applied to a Code-Division-Multiple-Access (CDMA) network (e.g. 3GPP2 IS-2000), Wideband-CDMA (WCDMA) network (e.g. 3GPP UMTS/High-Speed Packet Access (HSPA)) network or by way of generalization, to any network based on radio access technologies that utilize network-controlled radio resources or that does not maintain any knowledge of the status of device application level data exchanges. The specific examples and implementations described below although presented for simplicity in relation to UMTS networks are also applicable to these other network environments. Further, the network element is sometimes described below as the UTRAN. However, if other network types besides UMTS are utilized, the network element can be selected appropriately based on the network type. Further, the network element can be the core network in a UMTS system, where the core network is the one that makes transition decisions.

In a particular example, the present system and method provide for the transitioning from an RRC connected mode to a more battery efficient or radio resource efficient state or mode while providing for decision making capabilities at the network. In particular, the present method and apparatus provide for transitioning based on receipt of an indication from a UE indicating, either implicitly or explicitly, that a transition for the RRC state or mode associated with a particular signaling connection with radio resources should occur from one state or mode to another. As will be appreciated, such an indication or request could be an existing communication under current standards, for example a signaling connection release, or could be a new dedicated message to change the state of the UE, such as a “preferred RRC state request”. As used herein, an indication could refer to either scenario, and could incorporate a request.

The transition indication originated by the UE can be sent in some situations when one or more applications on the UE have completed an exchange of data and/or when a determination is made that the UE application(s) are not expected to exchange any further data. The network element can then use the indication and any information provided therein, as well as other information related to the radio resource, such as quality of service, Access Point Name (APN), Packet Data Protocol (PDP) context, historical information, among others, defined herein as a radio resource profile, to make a network specific decision about whether to transition the mobile device to another mode or state, or do nothing. The transition indication provided by the UE or mobile device can take several forms and can be sent under different conditions. In a first example, the transition indication can be sent based on a composite status of all of the applications residing on the UE. Specifically, in a UMTS environment, if an application on the UE determines that it is done with the exchange of data, it can send a “done” indication to a “connection manager” component of UE software. The connection manager can, in one embodiment, keep track of all existing applications (including those providing a service over one or multiple protocols), associated Packet Data Protocol (PDP) contexts, associated packet switched (PS) radio resources and associated circuit switched (CS) radio resources. A PDP context is a logical association between a UE and PDN (Public Data Network) running across a UMTS core network. One or multiple applications (e.g., an e-mail application and a browser application) on the UE may be associated with one PDP context. In some cases, one application on the UE is associated with one primary PDP context and multiple applications may be tied with secondary PDP contexts. The connection manager receives “done” indications from different applications on the UE that are simultaneously active. For example, a user may receive an e-mail from a push server while browsing the web. After the email application has sent an acknowledgment, it may indicate that it has completed its data transaction. The browser application may behave differently and instead make a predictive determination (e.g., using an inactivity timer) of when to send a “done” indication to the connection manager.

Based on a composite status of such indications from active applications, UE software can decide to send a transition indication to indicate or request the network that a transition from one state or mode to another should occur. Alternatively, the UE software can instead wait before it sends the transition indication and introduce a delay to ensure that the application is truly finished with data exchange and does not require to be maintained in a battery or radio resource intensive state or mode. The delay can be dynamic based on traffic history and/or application profiles. Whenever the connection manager determines with some probability that no application is expected to exchange data, it can send a transition indication to the network to indicate that a transition should occur. In a specific example, the transition indication can be a signaling connection release indication for the appropriate domain (e.g. PS domain) to request an idle mode transition. Alternatively, the transition indication could be a request for state transition within connected mode to the UTRAN.

As described below in further detail, based on the receipt of a transition indication and on a radio resource profile, a network element such as the UTRAN in a UMTS environment can decide to transition the UE from one state or mode to another.

Other transition indications are possible. For example, instead of relying on a composite status of all active applications on the UE, the UE software can, in an alternative embodiment, send a transition indication every time a UE application has completed an exchange of data and/or the application is not expected to exchange further data. In this case, the network element (e.g., the UTRAN), based on a radio resource profile for the UE as described with reference to FIG. 18 below, can utilize the indication to make a transitioning decision.

In yet another example, the transition indication could simply indicate that one or more applications on the UE completed a data exchange and/or that the UE application(s) are not expected to exchange any further data. Based on that indication and a radio resource profile for the UE, the network (e.g., UTRAN), can decide whether or not to transition the UE to a more appropriate state or mode of operation.

In a further example, the transition indication could be implicit rather than explicit. For example, the indication may be part of a status report sent periodically. Such a status report could include information such as whether a radio link buffer has data or could include information on outbound traffic.

In a further embodiment, a timer could exist on the UE to ensure that a transition indication may not be repeated until a time duration has elapsed (inhibit duration). This avoids the UE sending the transition indication message too frequently and further allows the network to make a determination by relying on messages that are triggered only under a given maximum frequency. The time duration could be measured by a timer whose value is preconfigured, or set by a network (indicated or signaled). If the value is set by a network, it could be conveyed in existing messages such as RRC Connection Request, RRC Connection release, Radio Bearer Setup or a System Information Broadcast, among others, and could be an information element in those messages.

The inhibit duration above may be based on the state the UE would like to transition to. For example the inhibit duration may be different, whether the mobile indicated its last preference for some RRC states/modes versus others. For example, it could be different if the mobile indicated a preference for idle mode, versus CELL_FACH, or versus CELL_PCH/URA states. In the case where the inhibit duration is set by the network, this may be achieved by the network indicating/sending two (or more) sets of values to the mobile, to be used depending on the scenario. Alternatively, the indication could be done in such a way that the appropriate inhibit duration value only is indicated/signaled to the mobile: for example, if the UE wants to transition to CELL_PCH, a different elapsed time duration could be set than if the UE wants to transition to idle.

The inhibit duration from above may be different, depending on which RRC state/mode the mobile currently is in (e.g., CELL_DCH/CELL_FACH versus CELL_PCH/URA_PCH, or in CELL_DCH VERSUS CELL_FACH, or CELL_PCH/URA_PCH).

The inhibit duration from above may be different, depending if the network has already acted on preference RRC state information from the mobile. Such recognition may happen on the network, or on the mobile side. In the first case, this may affect the inhibit values indicated/signaled by the network to the mobile. In this second case, different sets of inhibit duration values may be preconfigured or indicated/signaled by the network. As a particular case, the inhibit duration/functionality may be reduced or cancelled if the network has acted on preference RRC state information from the mobile, e.g., has initiated a state transition to a state indicated by the UE.

A maximum number of message per time-window (e.g., “no more than 15 messages every 10 minutes”) may be used/specified instead of, or in addition to, the inhibit duration.

Combinations of the above inhibition durations/maximum messages per time-window are possible.

The present disclosure therefore provides a method for transitioning states or modes on a user equipment comprising the steps of: receiving, at a network element, a transition indication; checking a radio resource profile for the user equipment; and making a transitioning decision at the network element based on the received transition indication and the radio resource profile.

The present disclosure further provides a network element adapted to make a transitioning decision, comprising: a communications subsystem adapted to receive a transition indication; memory; and a processor adapted to check a radio resource profile for a user equipment, the processor further adapted to make the transitioning decision based on the received transition indication and the radio resource profile.

The present disclosure further provides a user equipment adapted to initiate a transitioning decision, comprising: a communications subsystem adapted to communicate with a network; memory; and a processor adapted to determine if a state/mode transition is desirable and further adapted to send a transition indication to the network responsive to the determination, wherein the user equipment is adapted to receive a transitioning decision from the network based on the transitioning indication.

The present disclosure still further provides a method for initiating a transitioning decision from a user equipment comprising: determining if a state/mode transition is desirable at the user equipment; and sending a transition indication to the network responsive to the determination, whereby the user equipment receives a transitioning decision from the network based on the transitioning indication.

Reference is now made to FIG. 1. FIG. 1 is a block diagram showing the various modes and states for the radio resource control portion of a protocol stack in a UMTS network. In particular, the RRC can be either in an RRC idle mode 110 or an RRC connected mode 120.

As will be appreciated by those skilled in the art, a UMTS network consists of two land-based network segments. These are the Core Network (CN) and the Universal Terrestrial Radio-Access Network (UTRAN) (as illustrated in FIG. 8). The Core Network is responsible for the switching and routing of data calls and data connections to the external networks while the UTRAN handles all radio related functionalities.

In idle mode 110, the UE must request an RRC connection to set up the radio resource whenever data needs to be exchanged between the UE and the network. This can be as a result of either an application on the UE requiring a connection to send data, or as a result of the UE monitoring a paging channel to indicate whether the UTRAN or SGSN has paged the UE to receive data from an external data network such as a push server. In addition, the UE also requests an RRC connection whenever it needs to send Mobility Management signaling messages such as Location Area Update.

Once the UE has sent a request to the UTRAN to establish a radio connection, the UTRAN chooses a state for the RRC connection to be in. Specifically, the RRC connected mode 120 includes four separate states. These are CELL_DCH state 122, CELL_FACH state 124, CELL_PCH state 126 and URA_PCH state 128.

From idle mode 110 the UE autonomously transitions to the CELL_FACH state 124, in which it makes its initial data transfer, subsequent to which the network determines which RRC connected state to use for continued data transfer. This may include the network either moving the UE into the Cell Dedicated Channel (CELL_DCH) state 122 or keeping the UE in the Cell Forward Access Channel (CELL_FACH) state 124.

In CELL_DCH state 122, a dedicated channel is allocated to the UE for both uplink and downlink to exchange data. This state, since it has a dedicated physical channel allocated to the UE, typically requires the most battery power from the UE.

Alternatively, the UTRAN can maintain the UE in a CELL_FACH state 124. In a CELL_FACH state, no dedicated channel is allocated to the UE. Instead, common channels are used to send signaling in a small amount of bursty data. However, the UE still has to continuously monitor the FACH, and therefore it consumes more battery power than in a CELL_PCH state, a URA_PCH state, and in idle mode.

Within the RRC connected mode 120, the RRC state can be changed at the discretion of the UTRAN. Specifically, if data inactivity is detected for a specific amount of time or data throughput below a certain threshold is detected, the UTRAN may move the RRC state from CELL_DCH state 122 to the CELL_FACH state 124, CELL_PCH state 126 or URA_PCH state 128. Similarly, if the payload is detected to be above a certain threshold, then the RRC state can be moved from CELL_FACH state 124 to CELL_DCH state 122.

From CELL_FACH state 124, if data inactivity is detected for a predetermined time in some networks, the UTRAN can move the RRC state from CELL_FACH state 124 to a paging channel (PCH) state. This can be either the CELL_PCH state 126 or URA_PCH state 128.

From CELL_PCH state 126 or URA_PCH state 128, the UE must move to CELL_FACH state 124 in order to initiate an update procedure to request a dedicated channel. This is the only state transition that the UE controls.

Idle mode 110 and CELL_PCH state 126 and URA_PCH state 128 use a discontinuous reception cycle (DRX) to monitor broadcast messages and pages by a Paging Indicator Channel (PICH). No uplink activity is possible.

The difference between CELL_PCH state 126 and URA_PCH state 128 is that the URA_PCH state 128 only triggers a URA Update procedure if the UE's current UTRAN registration area (URA) is not among the list of URA identities present in the current cell. Specifically, reference is made to FIG. 2. FIG. 2 shows an illustration of various UMTS cells 210, 212 and 214. All of these cells require a cell update procedure if reselected to a CELL_PCH state. However, in a UTRAN registration area, each will be within the same UTRAN registration area (URA) 320, and thus a URA update procedure is not triggered when moving between 210, 212 and 214 when in a URA_PCH mode.

As seen in FIG. 2, other cells 218 are outside the URA 320, and can be part of a separate URA or no URA.

As will be appreciated by those skilled in the art, from a battery life perspective the idle state provides the lowest battery usage compared with the states above. Specifically, because the UE is required to monitor the paging channel only at intervals, the radio does not need to continuously be on, but will instead wake up periodically. The trade-off for this is the latency to send data. However, if this latency is not too great, the advantages of being in the idle mode and saving battery power outweigh the disadvantages of the connection latency.

Reference is again made to FIG. 1. Various UMTS infrastructure vendors move between states 122, 124, 126 and 128 based on various criteria. These criteria could be the network operator's preferences regarding the saving of signaling or the saving of radio resources, among others. Exemplary infrastructures are outlined below.

In a first exemplary infrastructure, the RRC moves between an idle mode and a CELL_DCH state directly after initiating access in a CELL_FACH state. In the CELL_DCH state, if two seconds of inactivity are detected, the RRC state changes to a CELL_FACH state 124. If, in CELL_FACH state 124, ten seconds of inactivity are detected then the RRC state changes to CELL_PCH state 126. Forty five minutes of inactivity in CELL_PCH state 126 will result in the RRC state moving back to idle mode 110.

In a second exemplary infrastructure, RRC transition can occur between an idle mode 110 and connected mode 120 depending on a payload threshold. In the second infrastructure, if the payload is below a certain threshold then the UTRAN moves the RRC state to CELL_FACH state 124. Conversely, if the data payload is above a certain payload threshold then the UTRAN moves the RRC state to a CELL_DCH state 122. In the second infrastructure, if two minutes of inactivity are detected in CELL_DCH state 122, the UTRAN moves the RRC state to CELL_FACH state 124. After five minutes of inactivity in the CELL_FACH state 124, the UTRAN moves the RRC state to CELL_PCH state 126. In CELL_PCH state 126, two hours of inactivity are required before moving back to idle mode 110.

In a third exemplary infrastructure, movement between idle mode 110 and connected mode 120 is always to CELL_DCH state 122. After five seconds of inactivity in CELL_DCH state 122 the UTRAN moves the RRC state to CELL_FACH state 124. Thirty seconds of inactivity in CELL_FACH state 124 results in the movement back to idle mode 110.

In a fourth exemplary infrastructure, the RRC transitions from an idle mode to a connected mode directly into a CELL_DCH state 122. In the fourth exemplary infrastructure, CELL_DCH state 122 includes two configurations. The first includes a configuration which has a high data rate and a second configuration includes a lower data rate, but still within the CELL_DCH state. In the fourth exemplary infrastructure, the RRC transitions from idle mode 110 directly into the high data rate CELL_DCH substrate. After 10 seconds of inactivity, the RRC state transitions to a low data rate CELL_DCH sub-state. Seventeen seconds of inactivity from the low data sub-state of CELL_DCH state 122 results in the RRC state changing it to idle mode 110.

The above four exemplary infrastructures show how various UMTS infrastructure vendors are implementing the states. As will be appreciated by those skilled in the art, in each case, if the time spent on exchanging actual data (such as an email) is significantly short compared to the time that is required to stay in the CELL_(—) DCH or the CELL_FACH states, this causes unnecessary current drain, making the user experience in newer generation networks such as UMTS worse than in prior generation networks such as GPRS.

Further, although the CELL_PCH state 126 is more optimal than the CELL_FACH state 124 from a battery life perspective, the DRX cycle in a CELL_PCH state 126 is typically set to a lower value than the idle mode 110. As a result, the UE is required to wake up more frequently in the CELL_PCH state 126 than in an idle mode 110.

The URA_PCH state 128 with a DRX cycle similar to that of the idle state 110 is likely the optimal trade up between battery life and latency for connection. However, URA_PCH state 128 is currently not implemented in the UTRAN. In some cases, it is therefore desirable to quickly transition to the idle mode as quickly as possible after an application is finished with the data exchange, from a battery life perspective.

Reference is now made to FIG. 3. When transitioning from an idle mode to a connected mode various signaling and data connections need to be made. Referring to FIG. 3, the first item to be performed is an RRC connection setup 310. As indicated above, this RRC connection setup 310 can only be torn down by the UTRAN.

Once RRC connection setup 310 is accomplished, a signaling connection setup 312 is started.

Once signaling connection setup 312 is finished, a ciphering and integrity setup 314 is started. Upon completion of this, a radio bearer setup 316 is accomplished. At this point, data can be exchanged between the UE and UTRAN.

Tearing down a connection is similarly accomplished in the reverse order, in general. The radio bearer setup 316 is taken down and then the RRC connection setup 310 is taken down. At this point, the RRC moves into idle mode 110 as illustrated in FIG. 1.

Although the current 3GPP specification does not allow the UE to release the RRC connection or indicate its preference for RRC state, the UE can still indicate termination of a signaling connection for a specified core network domain such as the Packet Switched (PS) domain used by packet-switched applications. According to section 8.1.14.1 of 3GPP TS 25.331, the signaling connection release indication procedure is used by the UE to indicate to the UTRAN that one of its signaling connections has been released. This procedure may in turn initiate the RRC connection release procedure.

Thus staying within the current 3GPP specifications, signaling connection release may be initiated upon the tearing down of the signaling connection setup 312. It is within the ability of the UE to tear down signaling connection setup 312, and this in turn according to the specification “may” initiate the RRC connection release.

As will be appreciated by those skilled in the art, if signaling connection setup 312 is torn down, the UTRAN will also need to clean up ciphering and integrity setup 314 and radio bearer setup 316 after the signaling connection setup 312 has been torn down.

If signaling connection setup 312 is torn down, the RRC connection setup is typically brought down by the network for current vendor infrastructures if no CS connection is active.

Using this for one of the specific transition indication examples mentioned above, if the UE determines that it is done with the exchange of data, for example if a “connection manager” component of the UE software is provided with an indication that the exchange of data is complete, then the connection manager may determine whether or not to tear down the signaling setup 312. For example, an email application on the device sends an indication that it has received an acknowledgement from the push email server that the email was indeed received by the push server. The connection manager can, in one embodiment, keep track of all existing applications, associated PDP contexts, associated PS radio resources and associated circuit switched (CS) radio bearers. In other embodiments a network element (e.g., the UTRAN) can keep track of existing applications, associated PDP contexts, QoS, associated PS radio resources and associated CS radio bearers. A delay can be introduced at either the UE or network element to ensure that the application(s) is (are) truly finished with data exchange and no longer require an RRC connection even after the “done” indication(s) have been sent. This delay can be made equivalent to an inactivity timeout associated with the application(s) or the UE. Each application can have its own inactivity timeout and thus the delay can be a composite of all of the application timeouts. For example, an email application can have an inactivity timeout of five seconds, whereas an active browser application can have a timeout of sixty seconds. A delay can further be introduced between repeated indications or state change requests. Based on a composite status of all such indications from active applications, as well as a radio resource profile and/or resend delay in some embodiments, the UE software decides how long it should wait before it sends a transition indication (for e.g., a signaling connection release indication or state change request) for the appropriate core network (e.g., PS Domain). If the delay is implemented at the network element, the element makes a determination of whether to and how to transition the UE, but only operates the transition after the delay has run its course.

The inactivity timeout can be made dynamic based on a traffic pattern history and/or application profile.

If the network element transitions the UE to idle mode 110, which can happen in any stage of the RRC connected mode 120 as illustrated in FIG. 1, the network element releases the RRC connection and moves the UE to idle mode 110 as illustrated in FIG. 1. This is also applicable when the UE is performing any packet data services during a voice call. In this case, the network may chose to release only the PS domain, and maintain the CS domain or alternatively may chose not to release anything and instead maintain both the PS and CS domains.

In a further embodiment, a cause could be added to the transition indication indicating to the UTRAN the reason for the indication. In a preferred embodiment, the cause could be an indication that an abnormal state caused the indication or that the indication was initiated by the UE as a result of a requested transition. Other normal (i.e., non-abnormal) transactions could also result in the sending of the transition indication.

In a further preferred embodiment, various timeouts can cause a transition indication to be sent for an abnormal condition. The examples of timers below are not exhaustive, and other timers or abnormal conditions are possible. For example, 10.2.47 3GPP TS 24.008 specifies timer T3310 as:

TIMER T3310 TIMER TIMER ON THE 1^(st), 2^(nd), 3^(rd), NUM. VALUE STATE CAUSE OF START NORMAL STOP 4^(th) EXPIRY Note 3 T3310 15 s GMM-REG- ATTACH REQ sent ATTACH ACCEPT Retransmission INIT received of ATTACH REQ ATTACH REJECT received

This timer is used to indicate an attachment failure. The failure to attach could be a result of the network or could be a radio frequency (RF) problem such as a collision or bad RF.

The attachment attempt could occur multiple times, and an attachment failure results from either a predetermined number of failures or an explicit rejection.

A second timer of 10.2.47 of 3GPP is timer T3330, which is specified as:

TIMER T3330 TIMER TIMER ON THE 1^(st), 2^(nd), 3^(rd), NUM. VALUE STATE CAUSE OF START NORMAL STOP 4^(th) EXPIRY Note 3 T3330 15 s GMM- ROUTING AREA ROUTING AREA Retransmission ROUTING - UPDATE UPDATE ACC received of the ROUTING UPDATING- REQUEST sent ROUTING AREA AREA UPDATE INITIATED UPDATE REJ received REQUEST message

This timer is used to indicate a routing area update failure. Upon expiry of the timer, a further routing area update could be requested multiple times and a routing area update failure results from either a predetermined number of failures or an explicit rejection.

A third timer of 10.2.47 of 3GPP is timer T3340, which is specified as:

TIMER T3340 TIMER TIMER ON THE 1^(st), 2^(nd), 3^(rd), NUM. VALUE STATE CAUSE OF START NORMAL STOP 4^(th) EXPIRY Note 3 T3340 10 s GMM-REG-INIT ATTACH REJ, DETACH REQ, PS signalling Release the PS (lu mode GMM-DEREG-INIT ROUTING AREA UPDATE REJ or connection signalling only) GMM-RA-UPDATING-INT SERVICE REJ with any of released connection and GMM-SERV-REO-INIT the causes #11, #12, proceed as (lu mode only) #13 or #15. described in ATTEMPTING-TO- ATTACH ACCEPT or ROUTING subclause UPDATE-MM AREA UPDATE ACCEPT is 4.7.1.9 GMM-REG-NORMAL-SERVICE received with “no follow-on proceed” indication.

This timer is used to indicate a GMM service request failure. Upon expiry of the timer, a further GMM service request could be initiated multiple times and a GMM service request failure results from either a predetermined number of failures or an explicit rejection.

Thus, instead of a transition indication cause limited to an abnormal condition and a release by the UE, the transition indication cause could further include information about which timer failed for an abnormal condition. In a specific example where a signaling connection release indication is used as a transition indication, the indication could be structured as:

SIGNALING CONNECTION RELEASE INDICATION IE type Information and Semantics Element/Group name Need Multi reference description Message Type MP Message type UE Information Elements Integrity check info CH Integrity check info 10.3.3.16 CN information elements CN domain identity MP CN domain identity 10.3.1.1 Signaling Release OP Signaling t3310 timeout, Indication Cause Release t3330 timeout, Indication t3340 timeout, Cause UE Requested Idle Transition

This message is used by the UE to indicate to the UTRAN a request to release an existing signaling connection. The addition of the signaling release indication cause allows the UTRAN or other network element to receive the cause of the signaling release indication, whether it was due to an abnormal condition, and what the abnormal condition was. Based on the receipt of the signaling connection release indication and a radio resource profile for the UE, an RRC connection release procedure is, in turn, permitted to be initiated at the UTRAN.

In one implementation of this example, the UE, upon receiving a request to release, or abort, a signaling connection from upper layers for a specific CN (core network) domain, initiates the signaling connection release indication procedure if a signaling connection is identified in a variable. For example, a variable ESTABLISHED_SIGNALING_CONNECTIONS, for the specific CN domain identified with the IE (information element) “CN domain identity” exists. If the variable does not identify any existing signaling connection, any ongoing establishment of a signaling connection for that specific CN domain is aborted in another manner. Upon initiation of the signaling connection release indication procedures in the CELL_PCH or URA_PCH states, the UE performs a cell update procedure using a cause “uplink data transmission”. When a cell update procedure is completed successfully, the UE continues with the signaling connection release indication procedures that follow.

Namely, the UE sets the information element (IE) “CN domain identity” to the value indicated by upper logical layers. The value of the IE indicates the CN domain whose associated signaling connection the upper layers are marking to be released. If the CN domain identity is set to the PS domain, and if the upper layer indicates the cause to initiate this request, then the IE “signaling release indication cause” is accordingly set. The UE further removes the signaling connection with the identity indicated by upper layers from the variable “ESTABLISHED_SIGNALING_CONNECTIONS”. The UE transmits a signaling connection release indication message on, e.g., the Dedicated Control Channel (DCCH) using acknowledged mode radio link control (AM RLC). Upon confirmation of successful delivery of the release indication message by the RLC, the procedure ends.

An IE “Signaling Release Indication Cause” is also used pursuant to an embodiment of the present disclosure. The release cause is aligned, for instance, with existing message definitions. The upper layer release cause message is structured, e.g., as:

IE type Information and Semantics Element/Group name Need Multi reference description Signaling Release MP Enumerated Indication Cause (UE Requested PS Data session end, T3310 expiry, T3330 expiry, T3340 expiry) In this example, the T3310, T3330, and T3340 expiries correspond to expiration of correspondingly numbered timers, identified previously. A cause value is settable, in one implementation, as a “UE Requested PS Data session end” rather than a “UE requested idle transition” to remove the UE indication of a preference for an idle transition and provide for the UTRAN to decide upon the state transition, although the expected result corresponds to that identified by the cause value. The extension to the signaling connection release indication is preferably, but not necessarily, a non-critical extension.

Reference is now made to FIG. 9. FIG. 9 is a flow chart of an exemplary UE monitoring whether or not to send a signaling connection release indication for various domains (e.g. PS or CS). The process starts in step 910.

The UE transitions to step 912 in which it checks to see whether an abnormal condition exists. Such an abnormal condition can include, for example, timer T3310, timer T3320, or timer T3340 expiring as described above. If these timers expire a certain predetermined number of times or if an explicit rejection is received based on the expiry of any of these timers, the UE proceeds to step 914 in which it sends a signaling connection release indication. The signaling connection release indication message is appended with a signaling release indication cause field. The signaling release indication cause field includes at least that the signaling release indication is based on an abnormal condition or state and one embodiment includes the specific timer that timed out to result in the abnormal condition.

Conversely, if in step 912 the UE finds that no abnormal condition exists, the UE proceeds to step 920 in which it checks whether further data is expected at the UE. This can, as described above, include when an email is sent and confirmation of the sending of the email is received back at the UE. Other examples of where the UE will determine that no further data is expected would be known to those skilled in the art.

If in step 920 the UE determines that the data transfer is finished (or in the case of a circuit-switched domain that a call is finished), the UE proceeds to step 922 in which it sends a signaling connection release indication in which the signaling release indication cause field has been added and includes the fact that the UE requested an idle transition or simply indicates an end to the PS session.

From step 920, if the data is not finished, the UE loops back and continues to check whether an abnormal condition exists in step 912 and whether the data is finished in step 920.

Once the signaling connection release indication is sent in step 914 or step 922, the process proceeds to step 930 and ends.

The UE includes functional elements, implementable, for instance, by applications or algorithms carried out through operation of a UE microprocessor or by hardware implementation, that form a checker and a transition indication sender. The checker is configured to check whether a transition indication should be sent. And a transition indication sender is configured to send a transition indication responsive to an indication by the checker that the transition indication should be sent. The transition indication may include a transition indication cause field.

In one implementation, the network is, instead, implicitly made aware of timing out of a timer, and the UE need not send a cause value indicating the timing out of the timer. That is to say, the timer starts timing upon authorization of the network. Cause codes are defined, and the cause codes are provided by the network to the UE. Such cause codes are used by the UE to initiate the timer. The network is implicitly aware of the reason for subsequent timing out of the timer, as the cause code sent earlier by the network causes the timer to start timing. As a result, the UE need not send a cause value indicating the timing out of the timer.

As suggested by FIG. 9 as well as the foregoing description, a cause is includable and sent together with a transition indication (e.g., a signaling connection release indication) to indicate: 1.) an abnormal condition as well as 2.) a normal condition (not an abnormal condition such as for example a request for a PS data session end and/or a transition to an idle mode). In various implementations, therefore, operations at the UE provide for the adding of the cause to the transition indication to indicate an abnormal condition, or, alternately, to indicate a preference for a request of an idle transition or of a PS data session end, i.e., normal operation. Such operation, of course, also includes UE operation in which a cause is added to the transition indication only when an indication of an abnormal condition is to be made. And, conversely, such operation also includes UE operation in which a cause is added to a transition indication only to indicate normal, i.e., non-abnormal, operations and transactions. That is to say, with respect to FIG. 9, in such alternative operation, if, at step 912, an abnormal condition exists, the yes branch is taken to the step 914 while, if an abnormal condition does not exist, then the UE proceeds directly to the end step 930. Conversely, in the other such alternative operation, subsequent to the start step 912 a path is taken directly to the data finished step 920. If the data is finished, the yes branch is taken to the step 920 and, thereafter, to the step 930. If the data is not finished at the step 920, the no branch is taken back to the same step, i.e., step 920.

Referring to FIG. 10, when a network element receives the transition indication in step 1010 (e.g., a signaling connection release indication as shown), the network element examines the transition indication cause field if present in step 1014 and in step 1016 checks whether the cause is an abnormal cause or whether it is due to the UE requesting an idle transition and/or PS data session end. If, in step 1016, the signaling connection release indication is of abnormal cause, the network node proceeds to step 1020 in which an alarm is noted for performance monitoring and alarm monitoring purposes. The key performance indicator can be updated appropriately.

Conversely, if in step 1016 the cause of the transition indication (e.g. signaling connection release indication) is not a result of an abnormal condition, or in other words is a result of the UE requesting a PS data session end or idle transition, the network node proceeds to step 1030 in which no alarm is raised and the indication can be filtered from the performance statistics, thereby preventing the performance statistics from being skewed. From step 1020 or step 1030 the network node proceeds to step 1040 in which the process ends.

The reception and examination of the transition indication may, based on a radio resource profile for the UE, result in the initiation by the network element of packet switched data connection termination or alternatively to a transition into another more suitable state.

As suggested above, in some implementations, the absence of a cause in a transition indication may also be used to determine whether the transition indication is a result of a normal or an abnormal condition and whether an alarm must be raised. For example, if a cause is added only to denote normal conditions (i.e., non-abnormal such as, e.g., a request for PS data session end and/or transition to idle mode), and the network element receives a transition indication with no cause added, the network element may infer from the absence of a cause that the transition indication is a result of an abnormal condition and raise an alarm. Conversely, in another example, if a cause is added only to denote abnormal conditions, and the network element receives a transition indication with no cause, the network element may infer from the absence of a cause that the transition indication is a result of a normal condition (e.g., request for PS data session end and/or transition to idle mode) and not raise an alarm.

As will be appreciated by those skilled in the art, step 1020 can be used to further distinguish between various alarm conditions. For example, a T3310 time out could be used to keep a first set of statistics and a T3330 time out could be used to keep a second set of statistics. Step 1020 can distinguish between the causes of the abnormal condition, thereby allowing the network operator to track performance more efficiently.

The network includes functional elements, implementable, for instance, by applications or algorithms carried out through operation of a processor or by hardware implementation, that form an examiner and an alarm generator. The examiner is configured to examine a transition indication cause field of the transition indication. The examiner checks whether the transition indication cause field indicates an abnormal condition. The alarm generator is configured to selectably generate an alarm if examination by the examiner determines the signaling connection release indication cause field indicates the abnormal condition.

In one implementation, upon reception of a signaling connection release indication, the UTRAN forwards the cause that is received and requests, from upper layers, for the release of the signaling connection. The upper layers then are able to initiate the release of the signaling connection. The IE signaling release indication cause indicates the UE's upper layer cause to trigger the RRC of the UE to send the message. The cause is possibly the result of an abnormal upper layer procedure. Differentiation of the cause of the message is assured through successful reception of the IE.

A possible scenario includes a scenario in which, prior to confirmation by the RLC of successful delivery of the signaling connection release indication message, reestablishment of the transmitting side of the RLC entity on the signaling radio bearer RB2 occurs. In the event of such an occurrence, the UE retransmits the signaling connection release indication message, e.g., on the uplink DCCH using AM RLC on signaling radio bearer RB2. In the event that an inter-RAT (radio access technology) handover from UTRAN procedure occurs prior to confirmation by the RLC of the successful delivery of the signaling connection release indication or request message, the UE aborts the signaling connection when in the new RAT.

In a further embodiment, instead of a “signaling connection release indication or request”, a “preferred state request” could be utilized. Functionality similar to that described in FIGS. 9 and 10 above would be applicable to this preferred state request indication.

In one embodiment, the preferred state request indication is used by the UE to give information to the UTRAN on a preferred RRC state, when it is aware that it is unlikely to need to send any more PS domain data for a prolonged duration, and in the case of no CS domain data for example. Such a message is sent from the UE to UTRAN on the DCCH using AM RLC, for example. An exemplary message is shown below.

Preferred RRC State Request Information IE type and Semantics Element/Group name Need Multi reference description Message Type MP Message type UE Information Elements Preferred RRC state MP Preferred request cause RRC state indication cause

A preferred RRC state indication cause information element is used by the UE to provide information to the UTRAN on a preferred RRC state following a trigger such as an application trigger, data transfer being complete, or other triggers as described herein. The IE could look like:

Information Type and Semantics Element/Group name Need Multi reference description Preferred RRC state MP Enumerated 1 spare value is indication cause (idle, needed CELL PCH, URA_PCH, CELL_FACH)

Reference is now made to FIG. 20. FIG. 20 illustrates the embodiment within which a preferred state request is sent from the UE to the UTRAN. The process starts at step 2010 and proceeds to step 2012 in which a check is made on the UE to determine whether the conditions at the UE are appropriate to send a change state request. Such conditions are described in the present disclosure, for example with reference to FIG. 11 below, and could include one or more applications on the UE determining that they are finished with data exchange.

If, in step 2012, the conditions are not appropriate to send the change state request the process loops on itself and continues to monitor until conditions are appropriate to send the change state request.

Once the conditions are appropriate the process proceeds to step 2020 in which a preferred state request is sent to the UTRAN. An exemplary preferred state request is shown in the tables above.

The process then proceeds to step 2022 in which a check is made to determine whether the preferred state request was successful. As would be appreciated by those skilled in the art this could mean that the UTRAN has successfully received the preferred state request and has initiated a state transition to a state indicated by the UE. If yes, the process proceeds to step 2030 and ends.

Conversely, if it is determined in step 2022 that the request was not successful, the process proceeds to step 2024 and waits for a time period. Such a wait could be implemented using an “inhibit duration” that would not allow the mobile to send another preferred state request message before a given duration has elapsed. Alternatively, the process could limit the number of preferred state request messages within a given time period (e.g., no more than 15 messages in 10 minutes). A combination of the inhibition duration and limiting the number of messages in a time duration could also be combined.

The duration could be predetermined, such as a value defined in the standards, could be set by a network element, for example, as part of an RRC connection request, an RRC connection release, a radio bearer set up or system information broadcast message. Further, the duration could be set based on a parameter within the preferred state request message. Thus, the duration could be longer if the UE is requesting a transition to CELL_PCH rather than idle.

The signaling of the duration by a network element could take the form of an information element such as:

Inhibit Preferred RRC State Request Information Type and Semantics Element/Group name Need Multi reference description Inhibit Preferred RRC State OP Enumerated( Request 30 secs, 1 min, 1 min 30 secs, 2 mins)

Once the process has waited for a predetermined time in step 2024 the process proceeds back to step 2012 to determine whether the conditions for sending a preferred state request still exist. If yes, the process loops back to step 2020 and 2022.

An exception may occur on RLC reestablishment or inter-RAT change. If a reestablishment of the transmitting side of the RLC entity occurs before the successful delivery of the preferred RRC state request message has been confirmed by the RLC, in one embodiment, the UE retransmits the preferred RRC state request message on the uplink DCCH using AM RLC.

In one embodiment, if an inter-RAT handover from UTRAN procedure occurs before the successful delivery of the preferred RRC state request message has been confirmed by the RLC, the UE aborts the signaling connection while in the new RAT.

On the network side, the process is handled similarly to that described with reference to FIG. 18 below.

Referring again to FIG. 1, in some cases it may be more desirable to be in the connected mode 120 in a state such as URA_PCH state 128 than in idle mode 110. For example, if the latency for connection to the CELL_DCH state 122 or the CELL_FACH state 124 in connected mode 120 is required to be lower, it is preferable to be in a connected mode 120 PCH state. There are a number of ways of accomplishing this such as, for example, by changing the 3GPP specifications to allow for the UE to request the UTRAN move it to a specific state (e.g., in this case the URA_PCH state 128).

Alternatively, the connection manager may take into account other factors such as what state the RRC connection is currently in. If, for example, the RRC connection is in the URA_PCH state, it may decide that it is unnecessary to move to idle mode 110 and thus no signaling connection release procedure is initiated.

In a further alternative, the network element (e.g. the UTRAN) may itself take into account other factors such as what state the RRC connection is currently in and if, for example, the RRC connection is in the URA_PCH state it may decide that it is unnecessary to move to idle mode 110 and instead simply transition the UE into a more suitable state instead of releasing the connection.

Reference is made to FIG. 4. FIG. 4A shows a current UMTS implementation according to the infrastructure “four” example above. As illustrated in FIG. 4, time is across the horizontal axes.

The UE starts in RRC idle state 110 and based on local data needing to be transmitted or a page received from the UTRAN, starts to establish an RRC connection.

As illustrated in FIG. 4A, RRC connection setup 310 occurs first, and the RRC state is in a connecting state 410 during this time.

Next, signaling connections setup 312, ciphering and integrity setup 314, and radio bearer setup 316 occurs. The RRC state is CELL_DCH state 122 during this. As illustrated in FIG. 4A, the time for moving from RRC idle to the time that the radio bearer is setup is approximately two seconds in this example.

Data is next exchanged. In the example of FIG. 4A this is achieved in about two to four seconds and is illustrated by step 420.

After data is exchanged in step 420, no data is being exchanged except for intermittent RLC signaling PDU as required and thus the radio resource is reconfigured by the network to move into a lower data rate DCH configuration after approximately ten seconds. This is illustrated in steps 422 and 424.

In the lower data rate DCH configuration, nothing is received for seventeen seconds, at which point the RRC connection is released by the network in step 428.

Once the RRC connection release is initiated in step 428, the RRC state proceeds to a disconnecting state 430 for approximately forty milliseconds, after which the UE is in an RRC idle state 110.

Also illustrated in FIG. 4A, the UE current consumption is illustrated for the period in which the RRC is in CELL_DCH state 122. As seen, the current consumption is approximately 200 to 300 milliamps for the entire duration of the CELL_DCH state. During disconnect and idle, about 3 milliamps are utilized, assuming a DRX cycle of 1.28 seconds. However, the 35 seconds of current consumption at 200 to 300 milliamps is draining on the battery.

Reference is now made to FIG. 4B. FIG. 4B utilizes the same exemplary infrastructure “four” from above, only now implementing the signaling connection release.

As illustrated in FIG. 4B, the same setup steps 310, 312, 314 and 316 occur and this takes the same amount of time when moving between RRC idle state 110 and RRC CELL_DCH state 122.

Further, the RRC data PDU exchange for the exemplary email at step 420 of FIG. 4A is also done at FIG. 4B and this takes approximately two to four seconds.

The UE in the example of FIG. 4B has an application specific inactivity timeout, which in the example of FIG. 4B is two seconds and is illustrated by step 440. After the connection manager has determined that there is inactivity for the specific amount of time, the UE sends a transition indication, which in this case is a signaling connection release indication in step 442 and in step 448, the network proceeds, based on the receipt of the indication and on a radio resource profile for the UE, to release the RRC connection.

As illustrated in FIG. 4B, the current consumption during the CELL_DCH step 122 is still about 200 to 300 milliamps. However, the connection time is only about eight seconds. As will be appreciated by those skilled in the art, the considerably shorter amount of time that the mobile stays in the CELL_DCH state 122 results in significant battery savings for an always on UE device.

Reference is now made to FIG. 5. FIG. 5 shows a second example using the infrastructure indicated above as infrastructure “three”. As with FIGS. 4A and 4B, a connection setup occurs which takes approximately two seconds. This requires the RRC connection setup 310, the signaling connection setup 312, the ciphering and integrity setup 314 and the radio bearer setup 316.

During this setup, the UE moves from RRC idle mode 110 to a CELL_DCH state 122 with an RRC state connecting step 410 in between.

As with FIG. 4A, in FIG. 5A RLC data PDU exchange occurs at step 420, and in the example of FIG. 5A takes two to four seconds.

According to the infrastructure three, RLC signaling PDU exchange receives no data and thus is idle for a period of five seconds in step 422, except for intermittent RLC signaling PDU as required, at which point the radio resource reconfigures the UE to move into a CELL_FACH state 124 from CELL_DCH state 122. This is done in step 450.

In the CELL_FACH state 124, the RLC signaling PDU exchange finds that there is no data except for intermittent RLC signaling PDU as required for a predetermined amount of time, in this case thirty seconds, at which point an RRC connection release by network is performed in step 428.

As seen in FIG. 5A, this moves the RRC state to idle mode 110.

As further seen in FIG. 5A, the current consumption during the DCH mode is between 200 and 300 milliamps. When moving into CELL_FACH state 124 the current consumption lowers to approximately 120 to 180 milliamps. After the RRC connector is released and the RRC moves into idle mode 110 the power consumption is approximately 3 milliamps.

The UTRA RRC Connected Mode state being CELL_DCH state 122 or CELL_FACH state 124 lasts for approximately forty seconds in the example of FIG. 5A.

Reference is now made to FIG. 5B. FIG. 5B illustrates the same infrastructure “three” as FIG. 5A with the same connection time of about two seconds to get the RRC connection setup 310, signaling connection setup 312, ciphering and integrity setup 314 and radio bearer setup 316. Further, RLC data PDU exchange 420 takes approximately two to four seconds.

As with FIG. 4B, a UE application detects a specific inactivity timeout in step 440, at which point the transition indication (e.g., Signaling connection release indication 442) is sent by the UE and as a consequence, the network releases the RRC connection in step 448.

As can be seen further in FIG. 5B, the RRC starts in an idle mode 110, moves to a CELL_DCH state 122 without proceeding into the CELL_FACH state.

As will be seen further in FIG. 5B, current consumption is approximately 200 to 300 milliamps in the time that the RRC stage is in CELL_DCH state 122 which according to the example of FIG. 5 is approximate eight seconds.

Therefore, a comparison between FIGS. 4A and 4B, and FIGS. 5A and 5B shows that a significant amount of current consumption is eliminated, thereby extending the battery life of the UE. As will be appreciated by those skilled in the art, the above can further be used in the context of current 3GPP specs.

Reference is now made to FIG. 6. FIG. 6 illustrates a protocol stack for a UMTS network.

As seen in FIG. 6, the UMTS includes a CS control plane 610, PS control plane 611, and PS user plane 630.

Within these three planes, a non-access stratum (NAS) portion 614 and an access stratum portion 616 exist.

NAS portion 614 in CS control plane 610 includes a call control (CC) 618, supplementary services (SS) 620, and short message service (SMS) 622.

NAS portion 614 in PS control plane 611 includes both mobility management (MM) and GPRS mobility management (GMM) 626. It further includes session management/radio access bearer management SM/RABM 624 and GSMS 628.

CC 618 provides for call management signaling for circuit switched services. The session management portion of SM/RABM 624 provides for PDP context activation, deactivation and modification. SM/RABM 624 also provides for quality of service negotiation.

The main function of the RABM portion of the SM/RABM 624 is to connect a PDP context to a Radio Access Bearer. Thus SM/RABM 624 is responsible for the setup, modification and release of radio resources.

CS control plane 610 and PS control plane 611, in the access stratum 616, sit on radio resource control (RRC) 617.

NAS portion 614 in PS user plane 630 includes an application layer 638, TCP/UDP layer 636, and PDP layer 634. PDP layer 634 can, for example, include Internet Protocol (IP).

Access Stratum 616, in PS user plane 630, includes packet data convergence protocol (PDCP) 632. PDCP 632 is designed to make the WCDMA protocol suitable to carry TCP/IP protocol between UE and RNC (as seen in FIG. 8), and is optionally for IP traffic stream protocol header compression and decompression.

The UMTS Radio Link Control (RLC) 640 and Medium Access Control (MAC) layers 650 form the data link sub-layers of the UMTS radio interface and reside on the RNC node and the User Equipment.

The Layer 1 (L1) UMTS layer (physical layer 660) is below the RLC/MAC layers 640 and 650. This layer is the physical layer for communications.

While the above can be implemented on a variety of mobile or wireless devices, an example of one mobile device is outlined below with respect to FIG. 7. Reference is now made to FIG. 7.

UE 700 is preferably a two-way wireless communication device having at least voice and data communication capabilities. UE 700 preferably has the capability to communicate with other computer systems on the Internet. Depending on the exact functionality provided, the wireless device may be referred to as a data messaging device, a two-way pager, a wireless e-mail device, a cellular telephone with data messaging capabilities, a wireless Internet appliance, or a data communication device, as examples.

Where UE 700 is enabled for two-way communication, it will incorporate a communication subsystem 711, including both a receiver 712 and a transmitter 714, as well as associated components such as one or more, preferably embedded or internal, antenna elements 716 and 718, local oscillators (LOs) 713, and a processing module such as a digital signal processor (DSP) 720. As will be apparent to those skilled in the field of communications, the particular design of the communication subsystem 711 will be dependent upon the communication network in which the device is intended to operate. For example, UE 700 may include a communication subsystem 711 designed to operate within the GPRS network or UMTS network.

Network access requirements will also vary depending upon the type of network 719. For example, in UMTS and GPRS networks, network access is associated with a subscriber or user of UE 700. For example, a GPRS mobile device therefore requires a subscriber identity module (SIM) card in order to operate on a GPRS network. In UMTS a USIM or SIM module is required. In CDMA, a RUIM card or module is required. These will be referred to as a UIM interface herein. Without a valid UIM interface, a mobile device may not be fully functional. Local or non-network communication functions, as well as legally required functions (if any) such as emergency calling, may be available, but mobile device 700 will be unable to carry out any other functions involving communications over the network 700. The UIM interface 744 is normally similar to a card-slot into which a card can be inserted and ejected like a diskette or PCMCIA card. The UIM card can have approximately 64K of memory and hold many key configurations 751, and other information 753 such as identification, and subscriber related information.

When required network registration or activation procedures have been completed, UE 700 may send and receive communication signals over the network 719. Signals received by antenna 716 through communication network 719 are input to receiver 712, which may perform such common receiver functions as signal amplification, frequency down conversion, filtering, channel selection and the like, and in the example system shown in FIG. 7, analog to digital (A/D) conversion. ND conversion of a received signal allows more complex communication functions such as demodulation and decoding to be performed in the DSP 720. In a similar manner, signals to be transmitted are processed, including modulation and encoding for example, by DSP 720 and input to transmitter 714 for digital to analog conversion, frequency up conversion, filtering, amplification and transmission over the communication network 719 via antenna 718. DSP 720 not only processes communication signals, but also provides for receiver and transmitter control. For example, the gains applied to communication signals in receiver 712 and transmitter 714 may be adaptively controlled through automatic gain control algorithms implemented in DSP 720.

Network 719 may further communicate with multiple systems, including a server 760 and other elements (not shown). For example, network 719 may communicate with both an enterprise system and a web client system in order to accommodate various clients with various service levels.

UE 700 preferably includes a microprocessor 738, which controls the overall operation of the device. Communication functions, including at least data communications, are performed through communication subsystem 711. Microprocessor 738 also interacts with further device subsystems such as the display 722, flash memory 724, random access memory (RAM) 726, auxiliary input/output (I/O) subsystems 728, serial port 730, keyboard 732, speaker 734, microphone 736, a short-range communications subsystem 740 and any other device subsystems generally designated as 742.

Some of the subsystems shown in FIG. 7 perform communication-related functions, whereas other subsystems may provide “resident” or on-device functions. Notably, some subsystems, such as keyboard 732 and display 722, for example, may be used for both communication-related functions, such as entering a text message for transmission over a communication network, and device-resident functions such as a calculator or task list.

Operating system software used by the microprocessor 738 is preferably stored in a persistent store such as flash memory 724, which may instead be a read-only memory (ROM) or similar storage element (not shown). Those skilled in the art will appreciate that the operating system, specific device applications, or parts thereof, may be temporarily loaded into a volatile memory such as RAM 726. Received communication signals may also be stored in RAM 726. Further, a unique identifier is also preferably stored in read-only memory.

As shown, flash memory 724 can be segregated into different areas for both computer programs 758 and program data storage 750, 752, 754 and 756. These different storage types indicate that each program can allocate a portion of flash memory 724 for their own data storage requirements. Microprocessor 738, in addition to its operating system functions, preferably enables execution of software applications on the mobile device. A predetermined set of applications that control basic operations, including at least data and voice communication applications for example, will normally be installed on UE 700 during manufacturing. A preferred software application may be a personal information manager (PIM) application having the ability to organize and manage data items relating to the user of the mobile device such as, but not limited to, e-mail, calendar events, voice mails, appointments, and task items. Naturally, one or more memory stores would be available on the mobile device to facilitate storage of PIM data items. Such PIM application would preferably have the ability to send and receive data items, via the wireless network 719. In a preferred embodiment, the PIM data items are seamlessly integrated, synchronized and updated, via the wireless network 719, with the mobile device user's corresponding data items stored or associated with a host computer system. Further applications may also be loaded onto the mobile device 700 through the network 719, an auxiliary I/O subsystem 728, serial port 730, short-range communications subsystem 740 or any other suitable subsystem 742, and installed by a user in the RAM 726 or preferably a non-volatile store (not shown) for execution by the microprocessor 738. Such flexibility in application installation increases the functionality of the device and may provide enhanced on-device functions, communication-related functions, or both. For example, secure communication applications may enable electronic commerce functions and other such financial transactions to be performed using the UE 700. These applications will however, according to the above, in many cases need to be approved by a carrier.

In a data communication mode, a received signal such as a text message or web page download will be processed by the communication subsystem 711 and input to the microprocessor 738, which preferably further processes the received signal for output to the display 722, or alternatively to an auxiliary I/O device 728. A user of UE 700 may also compose data items such as email messages for example, using the keyboard 732, which is preferably a complete alphanumeric keyboard or telephone-type keypad, in conjunction with the display 722 and possibly an auxiliary I/O device 728. Such composed items may then be transmitted over a communication network through the communication subsystem 711.

For voice communications, overall operation of UE 700 is similar, except that received signals would preferably be output to a speaker 734 and signals for transmission would be generated by a microphone 736. Alternative voice or audio I/O subsystems, such as a voice message recording subsystem, may also be implemented on UE 700. Although voice or audio signal output is preferably accomplished primarily through the speaker 734, display 722 may also be used to provide an indication of the identity of a calling party, the duration of a voice call, or other voice call related information for example.

Serial port 730 in FIG. 7 would normally be implemented in a personal digital assistant (PDA)-type mobile device for which synchronization with a user's desktop computer (not shown) may be desirable. Such a port 730 would enable a user to set preferences through an external device or software application and would extend the capabilities of mobile device 700 by providing for information or software downloads to UE 700 other than through a wireless communication network. The alternate download path may for example be used to load an encryption key onto the device through a direct and thus reliable and trusted connection to thereby enable secure device communication.

Alternatively, serial port 730 could be used for other communications, and could include as a universal serial bus (USB) port. An interface is associated with serial port 730.

Other communications subsystems 740, such as a short-range communications subsystem, is a further optional component which may provide for communication between UE 700 and different systems or devices, which need not necessarily be similar devices. For example, the subsystem 740 may include an infrared device and associated circuits and components or a Bluetooth™ communication module to provide for communication with similarly enabled systems and devices.

Reference is now made to FIG. 8. FIG. 8 is a block diagram of a communication system 800 that includes a UE 802 which communicates through the wireless communication network.

UE 802 communicates wirelessly with one of multiple Node Bs 806. Each Node B 806 is responsible for air interface processing and some radio resource management functions. Node B 806 provides functionality similar to a Base Transceiver Station in GSM/GPRS networks.

The wireless link shown in communication system 800 of FIG. 8 represents one or more different channels, typically different radio frequency (RF) channels, and associated protocols used between the wireless network and UE 802. A Uu air interface 804 is used between UE 802 and Node B 806.

An RF channel is a limited resource that must be conserved, typically due to limits in overall bandwidth and a limited battery power of UE 802. Those skilled in the art will appreciate that a wireless network in actual practice may include hundreds of cells depending upon desired overall expanse of network coverage. All pertinent components may be connected by multiple switches and routers (not shown), controlled by multiple network controllers.

Each Node B 806 communicates with a radio network controller (RNC) 810. The RNC 810 is responsible for control of the radio resources in its area. One RNC 810 controls multiple Node Bs 806.

The RNC 810 in UMTS networks provides functions equivalent to the Base Station Controller (BSC) functions in GSM/GPRS networks. However, an RNC 810 includes more intelligence, including, for example, autonomous handovers management without involving MSCs and SGSNs.

The interface used between Node B 806 and RNC 810 is an Iub interface 808. An NBAP (Node B application part) signaling protocol is primarily used, as defined in 3GPP TS 25.433 V3.11.0 (2002-09) and 3GPP TS 25.433 V5.7.0 (2004-01).

Universal Terrestrial Radio Access Network (UTRAN) 820 comprises the RNC 810, Node B 806 and the Uu air interface 804.

Circuit switched traffic is routed to Mobile Switching Centre (MSC) 830. MSC 830 is the computer that places the calls, and takes and receives data from the subscriber or from PSTN (not shown).

Traffic between RNC 810 and MSC 830 uses the Iu-CS interface 828. Iu-CS interface 828 is the circuit-switched connection for carrying (typically) voice traffic and signaling between UTRAN 820 and the core voice network. The main signaling protocol used is RANAP (Radio Access Network Application Part). The RANAP protocol is used in UMTS signaling between the Core Network 821, which can be an MSC 830 or SGSN 850 (defined in more detail below) and UTRAN 820. RANAP protocol is defined in 3GPP TS 25.413 V3.11.1 (2002-09) and TS 25.413 V5.7.0 (2004-01).

For all UEs 802 registered with a network operator, permanent data (such as UE 802 user's profile) as well as temporary data (such as UE's 802 current location) are stored in a home location registry (HLR) 838. In case of a voice call to UE 802, HLR 838 is queried to determine the current location of UE 802. A Visitor Location Register (VLR) 836 of MSC 830 is responsible for a group of location areas and stores the data of those mobile stations that are currently in its area of responsibility. This includes parts of the permanent mobile station data that have been transmitted from HLR 838 to the VLR 836 for faster access. However, the VLR 836 of MSC 830 may also assign and store local data, such as temporary identifications. UE 802 is also authenticated on system access by HLR 838.

Packet data is routed through Service GPRS Support Node (SGSN) 850. SGSN 850 is the gateway between the RNC and the core network in a GPRS/UMTS network and is responsible for the delivery of data packets from and to the UEs within its geographical service area. Iu-PS interface 848 is used between the RNC 810 and SGSN 850, and is the packet-switched connection for carrying (typically) data traffic and signaling between the UTRAN 820 and the core data network. The main signaling protocol used is RANAP (described above).

The SGSN 850 communicates with the Gateway GPRS Support Node (GGSN) 860. GGSN 860 is the interface between the UMTS/GPRS network and other networks such as the Internet or private networks. GGSN 860 is connected to a public data network PDN 870 over a Gi interface.

Those skilled in the art will appreciate that a wireless network may be connected to other systems, possibly including other networks, not explicitly shown in FIG. 8. A network will normally be transmitting at the very least some sort of paging and system information on an ongoing basis, even if there is no actual packet data exchanged. Although the network consists of many parts, these parts all work together to result in certain behaviors at the wireless link.

FIG. 11 illustrates a representation, shown generally at 1102, representative of operation of the UE pursuant to multiple, concurrent packet data communication service sessions. Here, two packet data services, each associated with a particular PDP context designated as PDP₁ and PDP₂ are concurrently active. The plot 1104 represents the PDP context activated to the first packet data service, and the plot 1106 represents the radio resource allocated to the first packet data service. And, the plot 1108 represents the PDP context activated to the second packet data service, and the plot 1112 represents the radio resource allocated to the second packet data service. The UE requests radio access bearer allocation by way of a service request, indicated by the segments 1114. And, the UE also requests radio bearer service release, indicated by the segments 1116 pursuant to an embodiment of the present disclosure. The service requests and service releases for the separate services are independent of one another, that is to say, are generated independently. In the exemplary illustration of FIG. 11, the PDP context and the radio resource for the associated PDP context are assigned at substantially concurrent times. And, the radio resource release is granted upon request by the UE, as shown, or when the RNC (Radio Network Controller) decides to release the radio resource.

Responsive to a radio resource release request, or other decision to release the radio resource, the network selectably tears down the radio resource associated with the packet data service. Radio release requests are made on a radio access bearer-by-radio access bearer basis and not on an entire signaling connection basis, thereby permitting improved granularity control of resource allocation.

In the exemplary implementation, a single packet data service is further formable as a primary service and one or more secondary services, such as indicated by the designations 1118 and 1122. The radio resource release is further permitting of identifying which of one or more primary and secondary services whose radio resource allocations are no longer needed, or otherwise are desired to be released. Efficient radio resource allocation is thereby provided. In addition, optimal utilization of the processor on the UE is provided, since the processor power that would have been allocated to unnecessary processing can now be better utilized for other purposes.

FIG. 12 illustrates parts of the communication system 800, namely, the UE 802 and the radio network controller (RNC)/SGSN 810/850 that operate pursuant to an embodiment of the present disclosure pertaining to the multiple, contiguous packet data service sessions. The UE includes apparatus 1126 and the RNC/SGSN includes apparatus 1128 of an embodiment of the present disclosure. The elements forming the apparatus 1126 and 1128 are functionally represented, implementable in any desired manner, including by algorithms executable by processing circuitry as well as hardware or firmware implementations. The elements of the apparatus 1128, while represented to be embodied at the RNC/SGSN, are, in other implementations, formed elsewhere at other network locations, or distributed across more than one network location.

The apparatus 1126 includes a detector 1132 and a transition indication sender 1134. In one exemplary implementation, the elements 1132 and 1134 are embodied at a session management layer, e.g., the Non-Access Stratum (NAS) layer defined in UMTS, of the UE.

In another exemplary implementation, the elements are embodied at an Access Stratum (AS) sublayer. When implemented at the AS sublayer, the elements are implemented as part of a connection manager, shown at 1136. When implemented in this manner, the elements need not be aware of the PDP context behavior or of the application layer behavior.

The detector detects when a determination is made to send a transition indication associated with a packet communication service. The determination is made, e.g., at an application layer, or other logical layer, and provided to the session management layer and the detector embodied thereat. Indications of detections made by the detector are provided to the radio resource release indication sender. The sender generates and causes the UE to send a transition indication that forms the service release request 1116, shown in FIG. 11.

In a further implementation, the transition indication includes a cause field containing a cause, such as any of the aforementioned causes described here and above, as appropriate or the cause field identifies a preferred state into which the UE prefers the network to cause the UE to be transitioned.

The apparatus 1128 embodied at the network includes an examiner 1142 and a grantor 1144. The examiner examines the transition indication, when received thereat. And, the transition grantor 1144 operates selectably to transition the UE as requested in the transition indication.

In an implementation in which the signaling is performed at a radio resource control (RRC) layer, the radio network controller, rather than the SGSN, performs the examination and transitioning of the UE. And, correspondingly, the apparatus embodied at the UE is formed at the RRC layer, or the apparatus otherwise causes the generated indication to be sent at the RRC level.

In an exemplary control flow, a higher layer informs the NAS/RRC layer, as appropriate, that the radio resource allocated to a particular PDP context is no longer required. An RRC-layer indication message is sent to the network. The message includes an RAB ID or RB ID that, e.g., identifies the packet data service, to the radio network controller. And, in response, operation of the radio network controller triggers a procedure to resolve to end the radio resource release, radio resource reconfiguration, or radio resource control connection release message to be returned to the UE. The RNC procedure is, e.g., similar, or equivalent to, the procedure set forth in 3GPP document TS 23.060, Section 9.2.5. The RAB ID, which is, e.g., advantageously utilized as the ID is the same as the Network Service Access Point Identifier (NSAPI) which identifies the associated PDP context, and application layers are generally aware of the NSAPI.

In a specific example, a radio resource release indication formed at, or otherwise provided to, the RRC layer, and sent at the RRC layer is represented, together with associated information, below. The indication when embodied at the RRC layer is also referred to as, e.g., a radio resource release indication.

IE type Information and Semantics Element/Group name Need Multi reference description Message Type MP Message type UE Information Elements Integrity check info CH Integrity check info RAB Information RAB List for release MP 1 to indication maxRABIDs >RAB ID for release MP RAB ID indication Preferred RRC state OP RRC state

FIG. 13 illustrates a message sequence diagram, shown generally at 1137, representing exemplary signaling generated pursuant to release of radio resources associated with a PDP context, such as that shown graphically in part of the graphical representation shown in FIG. 11. Release is initiated either by the UE or at the RNC, or other UTRAN entity. When initiated at the UE, e.g., the UE sends a radio resource release indication to the UTRAN.

Upon initiation, a radio access bearer (RAB) release request is generated, and sent, indicated by the segment 1138 by the RNC/UTRAN and delivered to the SGSN. In response, an RAB assignment request is returned, indicated by the segment 1140, to the RNC/UTRAN. And, then, as indicated by the segment 1142, the radio resources extending between the UE 802 and the UTRAN are released. A response is then sent, as indicated by segment 1144.

FIG. 14 illustrates a message sequence diagram shown generally at 1147, similar to the message sequence diagram shown in FIG. 13, but here in which resources of a final PDP context are released. Upon initiation, the RNC generates an lu release request 1150, which is communicated to the SGSN and responsive thereto, and the SGSN returns an Iu release command, indicated by the segment 1152. Thereafter, and as indicated by the segments 1154, the radio bearer formed between the UE and the UTRAN is released. And, as indicated by the segment 1156, the RNC/UTRAN returns an Iu release complete to the SGSN.

FIG. 15 illustrates a method flow diagram, shown generally at 1162, representative of the process of an embodiment of the present disclosure to release radio resources allocated pursuant to a PDP context.

After start of the process, indicated by the block 1164, a determination is made, indicated by the decision block 1166 as to whether a radio resource release indication has been received. If not, the no branch is taken to the end block 1168.

If, conversely, a radio access bearer release has been requested, the yes branch is taken to the decision block 1172. At the decision block 1172, a determination is made as to whether the radio access bearer that is to be released is the final radio access bearer to be released. If not, the no branch is taken to the block 1178, and the preferred state is set. Then radio access bearer release procedures are performed, such as that shown in FIG. 13 or such as that described in 3GPP document Section 23.060, subclause 9.2.5.1.1.

Conversely, if a determination is made at the decision block 1172 that the RAB is the last to be released, the yes branch is taken to the block 1186, an Iu release procedure, such as that shown in FIG. 14 or such as that described in 3GPP document section 23.060, subclause 9.2.5.1.2 is performed.

FIG. 16 illustrates a method flow diagram, shown generally at 1192, representative of the process of an embodiment of the present disclosure to release radio resources allocated pursuant to a PDP context.

After start of the process, indicated by the block 1194, a determination is made, indicated by the decision block 1196 as to whether there is an RAB (Radio access Bearer) to release. If not, the no branch is taken to the end block 1198.

If, conversely, a radio access bearer release has been requested, the yes branch is taken to the decision block 1202. At the decision block 1202, a determination is made as to whether the radio access bearer that is to be released is the final radio access bearer to be released. If not, the no branch is taken to the block 1204, where the RAB list is set, block 1206 where the preferred state is set, and block 1208 where radio access bearer release procedures are performed, such as that shown in FIG. 13 or such as that described in 3GPP document Section 23.060, subclause 9.2.5.1.1.

Conversely, if a determination is made at the decision block 1202 that the RAB is the last to be released, the yes branch is taken to the block 1212, and the domain is set to PC (Packet Switch). Then, as indicated by block 1214, a release cause is set. And, as indicated by the block 1216, a signaling connection release indication is sent on a DCCH. An Iu release procedure, such as that shown in FIG. 14 or such as that described in 3GPP document section 23.060, subclause 9.2.5.1.2 is performed.

FIG. 17 illustrates a method, shown generally at 1224, representative of the method of operation of an embodiment of the present disclosure. The method facilitates efficient utilization of radio resources in a radio communication system that provides for concurrent running of a first packet service and a second packet service. First, and as indicated by the block 1226, detection is made of selection to release a radio resource associated with a selected packet service of the first packet service and the second packet service. Then, and as indicated by the block 1228, a radio resource release indication is sent responsive to the detection of the selection to release the radio resource.

Then, at block 1212 the radio resource release indication is examined and then at block 1214 the grant of the release of the radio bearer is selectably granted.

In a further embodiment, the network may initiate a transition based on both the receipt of an indication from the user equipment or another network element and on a radio resource profile for the user equipment.

An indication as received from the user equipment or other network element could be any of the different transition indications described above. The indication can be passive and thus be merely a blank indication that a less battery intensive radio state should be entered. Alternatively the indication could be part of the regular indications sent from the UE which the network determines, possibly over time or a number of received indications, and the UE's radio resource profile that a less battery or radio resource intensive radio state should be entered. Alternatively, the indication could be dynamic and provide information to the network element about a preferred state or mode in which to transition. As with the above, the indication could contain a cause for the indication (e.g., normal or abnormal). In a further embodiment, the indication could provide other information about a radio resource profile, such as a probability that the user equipment is correct about the ability to transition to a different state or mode, or information about the application(s) that triggered the indication.

An indication from another network element could include, for example, an indication from a media or push-to-talk network entity. In this example, the indication is sent to the network entity responsible for transitioning (e.g. the UTRAN) when traffic conditions allow. This second network entity could look at traffic at an Internet protocol (IP) level to determine whether and when to send a transition indication.

In a further embodiment, the indication from the UE or second network element could be implicit rather than explicit. For example, a transition indication may be implied by the network element responsible for transitioning (e.g. the UTRAN) from device status reports on outbound traffic measurements. Specifically, status reporting could include a radio link buffer status where, if no outbound data exists, could be interpreted as an implicit indication. Such status reporting could be a measurement that can be repetitively sent from the UE that does not, by itself, request or indicate anything.

The indication could thus be any signal and could be application based, radio resource based, or a composite indication providing information concerning all of the user equipment's application and radio resources. The above is not meant to be limiting to any particular indication, and one skilled in the art would appreciate that any indication could be used with the present method and disclosure.

Reference is now made to FIG. 18. The process starts at step 1801 and proceeds to step 1810 in which a network element receives the indication.

Once the network receives the indication in step 1810, the process proceeds to step 1820 in which a radio resource profile for the user equipment is checked.

The term “radio resource profile”, as used herein, is meant to be a broad term that could apply to a variety of situations, depending on the requirements of a network element. In broad terms, the radio resource profile includes information about radio resources utilized by the user equipment.

The radio resource profile could include either or both static profile elements and dynamic or negotiated profile elements. Such elements could include an “inhibit duration and/or maximum indication/request messages per time-window” value, which could be part of the radio resource profile, either within or apart from the transition profile, and could be negotiated or static.

Static profile elements include one or more of the quality of service for a radio resource (e.g. RAB or RB), a PDP context, an APN that the network has knowledge of and a subscriber profile.

As will be appreciated by those skilled in the art, various levels of quality service could exist for a radio resource and the level of the quality of service could provide information to a network on whether to transition to a different state or mode. Thus if the quality of service is background, the network element may consider transitioning to idle more readily than if the quality of service is set to interactive. Further, if multiple radio resources have the same quality of service, this could provide an indication to the network on whether to transition the mobile device to a more suitable state or mode or to tear down the radio resources. In some embodiments, a primary and secondary PDP context could have a different quality of service, which could also affect the decision on whether to perform a state/mode transition.

Further, the APN could provide the network with information about the typical services that the PDP context utilizes. For example, if the APN is xyz.com, where xyz.com is typically used for the provision of data services such as email, this could provide an indication to the network about whether or not to transition to a different state or mode. This could further indicate routing characteristics.

In particular, the present method and apparatus can utilize the Access Point Name (APN) specified by the UE to set the transition profile between various states. This may be another way of describing the subscription of the UE. As will be appreciated, the Home Location Register (HLR) may store relevant information about subscribers, and could provide the radio network controller (RNC) with the subscription of the UE. Other network entities could also be used to store subscription information centrally. Whether using the HLR or other network entity, information is preferably pushed to other network components such as the RNC and SGSN, which map subscription information to relevant physical parameters used during data exchange.

The UTRAN could include or have access to a database or table in which various APNs or QoS parameters could be linked to a specific transition profile. Thus, if the UE is an always on device, this will be apparent from the APN and an appropriate transition profile for that APN could be stored at the UTRAN as part of the radio resource profile or be remotely accessible by the UTRAN. Similarly, if the QoS or a portion of the QoS parameter is used, or a dedicated message sent with a profile, this could signify to the UTRAN that a particular transition profile is desired based on a database query or a lookup in a table. Additionally, a multiplicity of behaviors beyond the RRC connected state transition profile can be specified by this means. These include, but are not limited to:

rate adaptation algorithms (periodicity of step/step size);

initial granted radio bearer;

maximal granted radio bearer;

minimize call setup time (avoid unnecessary steps such as traffic volume measurements); and

the air interface (GPRS/EDGE/UMTS/HSDPA/HSUPA/LTE).

Further, if there are multiple PDP contexts that have different QoS requirements but share the same APN IP address, such as a primary context, secondary context, and so forth, a different transition profile can be used for each context. This could be signaled to the UTRAN through QoS or dedicated messages.

If multiple active PDP contexts are concurrently utilized, the lowest common denominator between the contexts can be used. For RRC state transition, if one application has a first PDP context that is associated with a transition profile in which the system moves from CELL_DCH state to a CELL_PCH or Idle state quickly, and a second PDP context is associated with a transition profile in which the system is to stay in the CELL_DCH state longer, the second profile in which the CELL_DCH state is maintained longer will override the first profile.

As will be appreciated by those skilled in the art, the lowest common denominator can be considered in two different ways. Lowest common denominator, as used herein, implies a longest time required before transitioning to a different state. In a first embodiment, the lowest common denominator may be the lowest of the activated PDPs. In an alternative embodiment, the lowest common denominator may be the lowest of the PDPs that actually have active radio resources. The radio resources could be multiplexed in a number of different fashions but the end result is the same.

An exemplary case for such methods can be drawn for always on devices. As described, various APNs or QoS parameters can be linked to a specific behavior for always on. Consider initially granted radio resources that may be desirable based on an ‘always on’ profile. The network now has a means to ‘know’ that data bursts are short and bursty for always-on applications, such as email. For those skilled in the art, it is clearly seen that given this information, there is no incentive to save code space for trunking efficiency on the network. Thus a maximum rate may be allocated to an always on device with little risk of not reserving enough code space for other users. Additionally the UE benefits in receiving data more rapidly and also saves on battery life due to shorter ‘on time’. Again, to those skilled in the art, high data rates have very little effect on current draw since power amplifiers are fully biased regardless of data rate.

In the above embodiment, a lookup table can be used by the UTRAN to determine the resource control profile for radio resource(s) to be assigned for different applications for a given RRC connection for the UE. The profile can be based on user subscription and stored on the network side at a network entity such as HLR or alternatively at the RNC since the RNC will have more up to date traffic resources available (i.e., data rates that can be granted). If higher data rates can be achieved shorter timeouts may be possible.

Instead of APN, other alternatives such as the Quality of Service (QoS) parameters set in a Packet Data Protocol (PDP) Context activation or Modified PDP Context can be used. The QoS field can further include the QoS “allocation retention priority (service data unit could be used to infer traffic data volumes)” in case of multiple PDP contexts sharing the same APN address or a subscription profile to set the transition profile. Further alternatives include dedicated messages such as the indication message above to signal a resource control profile and information such as inhibit duration and/or maximum indication/request messages per time-window value.

The transition profile included in the radio resource profile could further include whether the state of the UE should be transitioned at all based on the type of application. Specifically, if the user equipment is being used as a data modem, a preference may be set either on the user equipment so transition indications are not sent or if knowledge of the preference is maintained at the network, that any transition indication received from the UE while being used as a data modem should be ignored. Thus the nature of the applications that are being run on the user equipment could be used as part of the radio resource profile.

A further parameter of a transition profile could involve the type of transition. Specifically, in a UMTS network, the user equipment may prefer to enter a CELL_PCH state rather than entering an idle state for various reasons. One reason could be that the UE needs to connect to a CELL_DCH state more quickly if data needs to be sent or received, and thus moving to a CELL_PCH state will save some network signaling and battery resources while still providing for a quick transition to the CELL_DCH state. The above is equally applicable in non-UMTS networks and may provide for a transition profile between various connected and idle states.

The transition profile may also include various timers including, but not limited to, inhibit duration and/or maximum indication/request messages per time-window, delay timers and inactivity timers. Delay timers provide a period which the network element will wait prior to transitioning to a new state or mode. As will be appreciated, even if the application has been inactive for a particular time period, a delay may be beneficial in order to ensure that no further data is received or transmitted from the application. An inactivity timer could measure a predetermined time period in which no data is received or sent by an application. If data is received prior to the inactivity timer expiring, typically the inactivity timer will be reset. Once the inactivity timer expires, the user equipment may then send the indication of step 1810 to the network. Alternatively, the user equipment may wait for a certain period, such as that defined for the delay timer, before sending the indication of step 1810.

Further, the delay timer or inhibit duration and/or maximum indication/request messages per time-window could vary based on a profile that is provided to the network element. Thus, if the application that has requested a transition to a different mode or state is a first type of application, such as an email application, the delay timer on the network element can be set to a first delay time, while if the application is of a second type such as an instant messaging application, the delay timer can be set to a second value. The values of the inhibit duration and/or maximum indication/request messages per time-window, delay timer or inactivity timer could also be derived by the network based on the APN utilized for a particular PDP.

As will be appreciated by those skilled in the art, the inactivity timer could similarly vary based on the application utilized. Thus, an email application may have a shorter inactivity timer than a browser application since the email application is expecting a discrete message after which it may not receive data. Conversely the browser application may utilize data even after a longer delay and thus require a longer inactivity timer.

The transition profile may further include a probability that a user equipment is correct requesting a transition. This could be based on compiled statistics on the rate of accuracy of a particular user equipment or application on the user equipment.

The transition profile may further include various discontinuous reception (DRX) time values. Further, a progression profile for DRX times could be provided in a transition profile.

The transition profile could be defined on an application by application basis or be a composite of the various applications on the user equipment.

As will be appreciated by those skilled in the art the transition profile could be created or modified dynamically when a radio resource is allocated and could be done on subscription, PS registration, PDP activation, RAB or RB activation or changed on the fly for the PDP or RAB/RB. The transition profile could also be part of the indication of step 1810. In this case, the network may consider the preferred RRC state indication to determine whether to allow the transition and to what state/mode. Modification could occur based on available network resources, traffic patterns, among others.

The radio resource profile is therefore comprised of static and/or dynamic fields. The radio resource profile used by a particular network may vary from other networks and the description above is not meant to limit the present method and system. In particular, the radio resources profile could include and exclude various elements described above. For example, in some cases the radio resource profile will merely include the quality of service for a particular radio resource and include no other information. In other cases, the radio resource profile will include only the transition profile. Still in other cases, the radio resource profile will include all of the quality of service, APN, PDP context, transition profile, among others.

Optionally, in addition to a radio resource profile, the network element could also utilize safeguards to avoid unnecessary transitions. Such safeguards could include, but are not limited to, the number of indications received in a predetermined time period, the total number of indications received, traffic patterns and historical data.

The number of indications received in a predetermined time period could indicate to the network that a transition should not occur. Thus, if the user equipment has sent, for example, five indications within a thirty second time period, the network may consider that it should ignore the indications and not perform any transitions. Alternatively, the network may determine to indicate to the UE that it should not send any further indications either indefinitely or for some configured or predefined time period. This could be independent of any “inhibit duration and/or maximum indication/request messages per time-window” on the UE.

Further, the UE could be configured not to send further indications for a configured, predefined or negotiated time period. The UE configuration could be exclusive of the safeguards on the network side described above.

The traffic patterns and historical data could provide an indication to the network that a transition should not occur. For example, if the user has received a significant amount of data in the past between 8:30 and 8:35 a.m. from Monday to Friday, if the indication is received at 8:32 a.m. on Thursday, the network may decide that it should not transition the user equipment since more data is likely before 8:35 a.m.

If multiple radio resources are allocated for the user equipment, the network may need to consider the complete radio resource profile for the user equipment. In this case, the radio resource profiles for each radio resource can be examined and a composite transition decision made. Based on the radio resource profile of one or multiple radio resources, the network can then decide whether or not a transition should be made.

In one embodiment, the network has a plurality of choices on how to proceed when it has received an indication in step 1810 and examined the radio resource profile or profiles in step 1820.

A first option is to do nothing. The network may decide that a transition is not warranted and thus not accept the user equipment indication to transition. As will be appreciated by those skilled in the art, doing nothing saves network signaling since the state is not changed and in particular since a transition is not triggered.

A second option is to change the state of the device. For example, in a UMTS network, the state of the device may change from CELL_DCH to CELL_PCH. In non-UMTS networks the state transition may occur between connected states. As will be appreciated by those skilled in the art, changing states reduces the amount of core network signaling when compared with a transition to idle mode. Changing the state can also save radio resources since the CELL_PCH state does not require a dedicated channel. Also, CELL_PCH is a less battery intensive state enabling the UE to preserve battery power.

A third option for the network is to keep the UE in the same state but release the radio resources associated with a particular APN or PDP context. This approach saves radio resources and signaling as the connection is maintained in its current state and does not need to be re-established. However, it may be less suitable for situations where UE battery life is a concern.

A fourth option for the network is to transition the UE to an Idle mode. In particular, in both UMTS and non-UMTS, the network may move from a connected mode to an Idle mode. As will be appreciated, this saves radio resources since no connection at all is maintained. It further saves the battery life on the user equipment. However, a greater amount of core network signaling is required to reestablish the connection.

A fifth option for the network is to change a data rate allocation, which will save radio resources, typically allowing more users to use the network.

Other options would be evident to those skilled in the art.

The decision of the network on which of the five options to utilize will vary from network to network. Some overloaded networks may prefer to preserve radio resources and thus would choose the third, fourth or fifth options above. Other networks prefer to minimize signaling and thus may choose the first or second options above.

The decision is shown in FIG. 18 at step 1830 and will be based on network preferences along with the radio resource profile for the user equipment. The decision is triggered by the network receiving an indication from the user equipment that the user equipment would like to transition into another state e.g. into a less battery intensive state.

Reference is now made to FIG. 19. FIG. 19 illustrates the simplified network element adapted to make the decisions shown in FIG. 18 above. Network element 1910 includes a communications subsystem 1920 adapted to communicate with user equipment. As will be appreciated by those skilled in the art communications subsystem 1920 does not need to directly communicate with user equipment, but could be part of a communications path for communications to and from the user equipment.

Network element 1910 further includes a processor 1930 and a storage 1940. Storage 1940 is adapted to store preconfigured or static radio resource profiles for each user equipment being serviced by network element 1910. Processor 1930 is adapted to, upon receipt of an indication by communications subsystem 1920, consider the radio resource profile for the user equipment and to decide on a network action regarding transitioning the user equipment. As will be appreciated by those skilled in the art, the indication received by communications subsystem 1920 could further include a portion of or all of the radio resource profile for the user equipment that would then be utilized by processor 1930 to make the network decision concerning any transition.

Based on the above, a network element therefore receives an indication from the user equipment that a transition might be in order (such as for example when a data exchange is complete and/or that no further data is expected at the UE). Based on this indication, the network element checks the radio resource profile of the user equipment, which could include both static and dynamic profile elements. The network element may further check safeguards to ensure that unnecessary transitions are not occurring. Based on the checks, the network element could then decide to do nothing or to transition to a different mode or state, or to tear down a radio resource. As will be appreciated, this provides the network more control of its radio resources and allows the network to configure transition decisions based on network preferences rather than merely user equipment preferences. Further, in some cases the network has more information than the device concerning whether to transition. For example, the user equipment has knowledge of upstream communications and based on this may decide that the connection may be torn down. However, the network may have received downstream communications for the user equipment and thus realized that it cannot tear down the connection. In this case, a delay can also be introduced using the delay timer to provide the network with more certainty that no data will be received for user equipment in the near future.

The embodiments described herein are examples of structures, systems or methods having elements corresponding to elements of the techniques of this disclosure. This written description may enable those skilled in the art to make and use embodiments having alternative elements that likewise correspond to the elements of the techniques of this disclosure. The intended scope of the techniques of this disclosure thus includes other structures, systems or methods that do not differ from the techniques of this disclosure as described herein, and further includes other structures, systems or methods with insubstantial differences from the techniques of this disclosure as described herein. 

The invention claimed is:
 1. A method comprising: receiving, at a network element from a user equipment, an indication message including a cause value; checking a radio resource profile for the user equipment, wherein the radio resource profile reflects transition information associated with the user equipment; and making, at the network element, a transition decision for the user equipment to transition to a more battery efficient or radio resource efficient state based on the received cause value and the radio resource profile and not to transition to a more battery efficient or radio resource efficient state if more than a predetermined number of indication messages are received during a predetermined time period.
 2. The method of claim 1 wherein the indication message is triggered by an application layer on the user equipment.
 3. The method of claim 1 wherein the radio resource profile includes static information.
 4. The method of claim 1 wherein the radio resource profile includes one or more of: an access point name, a quality of service associated with a radio bearer, a quality of service associated with a radio access bearer, a packet data protocol context, or historical information for the user equipment.
 5. The method of claim 1 wherein the radio resource profile includes a state transition profile.
 6. The method of claim 5 wherein the state transition profile includes information reflecting whether the state of the user equipment should enter transition, state transition preferences, delay or inactivity timer values, or a probability that the user equipment is correct to request a state transition.
 7. The method of claim 5 wherein the state transition profile is application specific.
 8. The method of claim 5 wherein the state transition profile is a composite of state transition profiles.
 9. A network element comprising: a communications subsystem adapted to receive an indication message including a cause value; memory; and a processor adapted to check a radio resource profile for a user equipment, the processor further adapted to make a transition decision to transition the user equipment to a more battery efficient or radio resource efficient state based on the received cause value and the radio resource profile and not to transition the user equipment to a more battery efficient or radio resource efficient state if more than a predetermined number of indication messages are received during a predetermined time period, wherein the radio resource profile reflects transition information associated with the user equipment.
 10. The network element of claim 9 wherein the indication message is triggered by an application layer on the user equipment.
 11. The network element of claim 9 wherein the radio resource profile includes static information.
 12. The network element of claim 9 wherein the radio resource profile information includes one or more of an access point name, a quality of service associated with a radio bearer, a quality of service associated with a radio access bearer, a packet data protocol context, or historical information for the user equipment.
 13. The network element of claim 9 wherein the radio resource profile includes a state transition profile.
 14. The network element of claim 13 wherein the state transition profile includes information reflecting whether the state of the user equipment should enter transition, state transition preferences, delay or inactivity timer values, or a probability that a user equipment is correct to request a state transition.
 15. The network element of claim 13 wherein the state transition profile is application specific.
 16. The network element of claim 13 wherein the state transition profile is a composite of state transition profiles.
 17. The network element of claim 9 wherein the memory is adapted to store the radio resource profile. 